Trends in the temperature dependency of segmental relaxation in

Trends in the temperature dependency of segmental relaxation in tetramethylbisphenol A polycarbonate/polystyrene blends. K. L. Ngai, C. M. Roland, J. ...
1 downloads 0 Views 542KB Size
3906

Macromolecules 1992,25, 3906-3909

Trends in the Temperature Dependency of Segmental Relaxation in TMPC/PS Blends K. L. Ngai and C. M. Roland’ Naval Research Laboratory, Washington, D.C. 20375-5000

J. M. O’Rsilly and J. S. Sedita Corporate Research Laboratories, Eastman Kodak Company, Rochester, New York 14650-2110 Received January 20, 1992; Revised Manuscript Received April 7, 1992 ABSTRACT A model to account for the composition dependence and shape of the relaxation spectra of miscible blends in the glass transition zone is applied to dielectric measurements on tetramethyLBiapheno1 A polycarbonate (TMPC)mixed with polystyrene (PS). The shape of the dispersion associatedwith segmental relaxation is governed primarily by the fluctuations in the degree of cooperativityassociatedwith the distribution in local composition arising from concentration fluctuations. A blend of fixed composition possesses a distribution of local environments; these effect a distribution in the degree of cooperativity of the segmental relaxation of locally rearranging chain units. Pure PS has a lower TBthan TMPC. Hence, in the blend before cooperative dynamics is considered, PS chains willtend to have segmentallyrelaxed when segmental relaxation of TMPC is considered. The dynamical constraints imposed by PS segments in a local environment of TMPC are thus mitigated, allowing TMPC segmental relaxation to proceed with a lower degree of intermolecular cooperativity than is the case in less PS-rich environments. The temperature dependence of the frequencytemperature shift factors for the blend are governed by the degree of intermolecular cooperativity of the segmental relaxation. Hence, there exists a direct and verifiable relation between frequency and temperature dependencies of the mixture. The present data on TMPCJPS, though not sufficient to entirely demonstrate such a relationship, are nevertheless consistent with the predicted relation.

Introduction Miscible polymer blends reveal new physics not encountered in neat Their segmentalrelaxation behavior, for example, is an intriguing area of research. The mechanical and dielectric glass transition dispersions in some miscible blends are unusually broad, exhibiting an extraordinary low-frequency tail and a strong temperature dependence. These characteristics are seen in miscible blends of 1,4-polyisoprene and poly(viny1as well as poly(viny1methyl ether) and polystyrene? which will be referred to asPIP/PVE and PVME/ PS, respectively. Although this behavior is closelyrelated to the distribution of segment environments arising from concentrationfluctuations,the constructionof a theoretical model to describe the segmental dynamics of the blend is a nontrivial task. The salient features of segmental relaxation in these blends have been explained rather well by an extension of the coupling model of relaxation.* In blends of PIP/PVE, environments richer in the latter confer to locally rearranging segments a larger degree of intermolecular coupling (stronger intermolecular constraints), due to the higher Tgand intrinsically greater capacity for strong intermolecular coupling of pure PVE. In a pure polymer the strength of the intermolecular couplingof segmentalrelaxation depends on the chemical structure of the monomer units.g In PVE the inflexible vinyl moietiesprojecting from the chain units inducelarger intermolecular coupling than occurs in 1,4-polyisoprene (PIP), whose unsaturated carbons are part of the chain backbone. Dynamic mechanical measurements have directly demonstrated that the coupling parameter, which provides a measure of the strength of the intermolecular coupling, is larger in PVE (n = 0.74) than for PIP (n = 0.501.’

From dielectric relaxation measurements it is known that neat PVME and PS have comparable coupling parameters.10 In their blends, therefore, it is principally the slower rate of intramolecular conformational transi-

tions by PS (due to its higher glass transition temperature) that causes PVME in environments richer in PS to have larger intermolecular coupling and, consequently, be associated with larger values of the couplingparameter. Dielectric relaxation studies of blends offer advantages over mechanical measurements since in favorable cases one component will be the main contributor to the dielectricspectrum. SincePVME has a much larger dipole moment than does PS, PVME dominates the dielectric response of their blends. Dielectric spectra from these blends can provide information on the influence of local environment on the segmental relaxation of PVME. By utilizing the coupling model to analyze isothermal data taken at various temperatures, the dependence of n of PVME on local composition was deduced.* The coupling parameter associated with local environments rich in PVME is found to be close to that of pure PVME (ca. 0.56). An increasing local concentration of PS has the effect of increasing the degree of intermolecularcoupling, with a value of n as large as 0.75 deduced for PVME in some PS-rich environments. The coupling model also offers the verifiable prediction of a correlation between the n’s and the temperature dependencies of segmental relaxation for PVME in the various local environments. The anticipated correlation was borne out by the experimental data. The PS segmental dynamics in the same blend could not be measured in this dielectricinvestigation. However, theoretically we can describe the frequency and temperature dependencies of segmental dynamics of PS in the various local environment and the trends of their variations with blend composition. Recently, another miscible blend of TMPC and PS was studied using dielectric spectroscopy.11J2 At 1 kHz, the maximum loss tangent of pure TMPC is about a factor of 10 larger than that of pure PS, implying that TMPC dominates the dielectric response of the blends except at low TMPC concentration. With respect to coupling, TMPC plays the role of PS in PS/PVME blends. Hence,

0024-9297/92/2225-3906$03.00/00 1992 American Chemical Society

Macromolecules, Vol. 25,No. 15, 1992

Segmental Relaxation in TMPC/PS Blends 3907

the situation that we can theoretically describe segmental dynamics of PS which could not be measured is circumvented by study of TMPC segmental relaxation in the TMPC/PS blend. In fact the data obtained on the segmental relaxation of TMPC in TMPC/PS blends reveal a somewhat different manifestation of the effect of concentrationfluctuationsfrom the results seen previously for PVME in PVME/PS blends and PIP in PIP/PVE blends. In this paper, the properties of segmental relaxation of TMPC in TMPC/PS will be discussed with emphasis on differences from the behavior of PVME relaxation seen in PVME/PS blends. Predictions of the coupling model are compared with the dielectricrelaxation data presently available. Expected Properties of Segmental Relaxation of TMPC in TMPC/PS Blends In the dielectric and enthalpy relaxation studies of TMPC/PS mixtures,11J2measurements obtained on the pure components make evident that large differences exist between both the Tis and the coupling parameters of the two pure polymers. This is exactly the situation in the case of PVE/PIP1and PVME/PS.4 Segmentalrelaxation of TMPC in PS/TMPC blends should have properties similar to that of PVE in PIP/PVE blends and that of PS in PVME/PS blends. In the latter case, although the coupling parameters measured dielectrically for pure PS and pure PVME are about the same and only the condition of a large difference in Tgof the polymers holds, this condition is sufficient to effect significant differences in the intermolecularcoupling strength of these components in the blend. According to the coupling scheme, addition of PS molecules that have less intermolecular coupling (smaller n for pure PS) effectively lowers the coupling parameter for TMPC segmental relaxation in any of its local environments in which PS replaces TMPC. In addition, the fact that pure PS has a lower Tgimplies that in the blend PS chains will tend to be segmentallyrelaxed when segmental relaxation of TMPC is considered. Under this circumstance, the dynamical constraints imposed by the PS segments in a local environment of TMPC have been completely mitigated. A dynamic entropy formulation of the coupling scheme13will lead to the conclusion that the coupling parameter n for TMPC segmental relaxation in that local environment of the blend is smaller than that of pure TMPC. Due to the concentration fluctuations inherent to mixtures, a single blend of fixed composition possesses a myriad of local environments. This distribution of local environmentseffectsa distribution of couplingparameters. According to the coupling scheme, TMPC segments in a local environment characterized by a coupling parameter n will relax in accordance with the Kohlrausch-WilliamsWatts stretched exponential function8J3 $o(t)= e x ~ [ - ( t / 7 * ~ ~ ( n ) P ”

(1) The apparent relaxation time T * T M ~ c (is~ related ) to the (oneof the two relaxation couplingparameter n and TO-C times in the Hall-Helfand relaxation function that describes the segmental relaxation of a TMPC chain) as T*TMpC(n)

= [(I - n)u,”ToTMpC]l’(l-n)

(2)

where l/o, defines a characteristic time for the intermolecular couplingsto begin to manifest themselves (for neat polymers wc is typically of the order of 1010 to 10118-1 8). The relaxation of TMPC segments is modeled with the assumption that concentration fluctuations produce a

Gaussian-distributed range of values for the coupling parameters reflecting the cooperative dynamics of their various local environments. The measured reponse is the sum over the distribution of n for all local environments. In the present case a smaller n in the distribution corresponds to local environments richer in PS than the average for the TMPC/PS blend. The experimental dielectric relaxation loss spectra measured isothermally at various temperatures are describedusing the expression

eXp[-(t/ T * T M ~ C ( ~ ~ Tl-n]M1~eXp[-ht] C , ~ ) ) dt dn (3) where A q ~ p is c the TMPC relaxation strength, R is the mean and a is the variance of the normal distribution of couplingparameters, and T*TMPC(+WC,~) (‘~*TMPC(~)) is calculated via eq 2. In addition to the distribution in coupling parameters, a distribution of T O T M ~ C ’ S among the local environments is possible. For the sake of simplicity of representation, this possibility is not incorporated explicitly in eq 3. Furthermore, for the purpose of this paper, it is immaterial whether or not such a distribution is included. In eq 3, the contribution from PS has been neglected because Acps is small. However, this approximation is expected to break down in mixtures with low TMPC content, as is seen later. It is important to distinguish between the variable n, characterizingthe degree of intermolecular cooperativity associated with a given local environment, and a, which represents the average couplingparameter for the mixture. From the discussion above a is expected to be a monotonicallydecreasingfunction of the total PS concentration. Note that this a is not obtainable by direct fitting of eq 1 to the measured segmental relaxation, since miscible blending gives rise to heterogeneous broadening of the dispersion,as described by eq 3. Generally,the relaxation function for blends will not conform to the form of the stretched exponential function. Isothermal dielectric measurements carried out over a wide frequency range will bring out properties of C”TM~C( w ) in the blend that can be anticipated from eqs 2 and 3. For example, consider the shift factors defined by where TR is an arbitrary reference temperature used to describe the temperature dependence of the effective relaxation time of segmental motion of TMPC in local environments having coupling parameter n. According to eq 2, these shift factors are related to the shift factors aO,TMpC for the primitive relaxation time ~ O T M ~ Cby log [aTMpc(n,T)l = - n)) log aO,TMpC = (1/(1- n)) 1% [70,TMpC(T)/rO,TMpC(T,)1 (5) Hence, the observed temperature dependence will be governed by the intermolecular cooperativity. From eq 5 it follows that TMPC segments in local environments richer in TMPC, characterized by stronger coupling (larger n), should exhibit a more marked dependence on kmperature. It is also expected that the lower frequency (longer time) dielectric response arises from contributions of TMPC segmentsin local environmentsricher in TMPC. This is a direct consequence of eq 2 which predicts longer 7*TMpC(n)for larger n because, under the usual experimental conditions,the product o , T O ~ T , ~ C is a number much greater than unity.

3908 Ngai et al.

Macromolecules, Vol. 25, No. 15, 1992 Table I

PSlTMPC 100/0 80120 50150 40160 20180

0/100

T..nsc ( '0

T. ('0

104 115 136 142 162 192

90.3 112.3 130.5 139.7 160.8 183.2

Cr,

c1

_ _ _ _ _ _ _ ~ ~ ~

10.1 11.0 12.0 12.7 11.7 8.9

Dielectric Relaxation Data Small-angleneutron scatteringmeasurements have been carried out on blends of PS and TMPC, from which the interaction parameter x as well as the correlation length of the concentration fluctuations were determined.14 All x values are negative over the composition range from 10/90to 90/10. The correlationlength of the concentration fluctuations is approximately twice the segment length of the components, implying that the mixing of this blend is effectively at the segmental level. The influence of concentration fluctuations on the relaxation behavior in mixtures is affected by this correlation length. Presumably, for a sufficiently small correlation length the concentration fluctuations will be averaged out with regard to their effect on segmental relaxation. This implication can only be assessed when dielectric measurements of segmental relaxation on TMPC/PS blends of various thermodynamic stability (various correlations lengths) become available. Dielectric measurements have been reported at various compositions in the range 1-100 kHz.11J2 Dielectriclosspeaks were obtained byfrequencytemperature superposition using the WLF equation

where Tg,DSC is the calorimetric glass transition temperature measured at 20 deg/min. The parameters c1 and c2 in eq 6 were determined by nonlinear regression analysis of the logarithmic frequency versus the temperature of maximum loss data. These results have been reported elsewhere.11J2 In this paper we follow previous work9J5 on segmental relaxation of pure polymers to define Tgas the temperature at which the relaxation time equals 100 s (r*(Tg)= lo28). From the relation, 7 = (27rfl-l,between relaxation time and frequencyand using eq 6, the followingexpression is obtained for the shift factor a(T) (=T*(7')/7(Tg)) log a(7') = log r(Tg)- 2.0 -

c,Tg(x + a) c2 + Tg(x+ a)

(7)

where is the temperature difference variable normalized to Tg and a=

Tg,DSC m

I

1

51 28 42 35 22 29

- Tg

lg

The quantities Tg,Dsc,c1, and c2 given previouslyll and T g determined here are listed in Table I for several blends and the pure polymers. Results The dielectricdata presently available are not extensive enough to make a detailed analysis based on eq 3 worthwhile. Previously,this approach was used to deduce the coupling parameter associated with several local

100% PS

-

------

6O%TMPC

.................

80% TMPC

-

100%TMPC-

50% TMPC

-

-

0.00

0.02 0.04 0.06 0.08 0.10 0.12

0.14

Figure 1. Temperaturedependence of the shift factors for the frequency associated with the peak local environments for the

indicated compositions.

environments (correspondingto different frequencies in the spectrum) for a single blend of PVME/PS.4 The variation of the coupling parameter across the dielectric dispersion conformed to expectations that the response at lower frequenciesarises primarily from PVME segments in local environments having (1)a higher concentration of PS, (2) larger coupling parameters, and (3) a stronger dependence of shift factor on the normalized inverse temperature Tg/Tor the temperature difference variable (T - Tg)/Tg.We forgo such a detailed analysis herein; considerationwill be limited to only those TMPC segments which by virtue of their local environment govern the response at the peak of the dielectric loss (henceforth referred to as "peak local environments"). From the data for various compositions of TMPC and PS a comparison can be made of the shift factors for the peak local environments and their temperature dependence. Blends with higher TMPC concentrationswill have peak local environments richer in TMPC; larger coupling parameters are expected for TMPC segmentalrelaxations of these peak local environments. From the dependence of the shift factor on n (eq 5), when the shift factors given by eq 7 are plotted versus (T - Tg)/Tg,the steepest variation is predicted for the composition with highest TMPC concentration; Le., pure TMPC. Such plots are displayed in Figure 1,where it is seen that the rank ordering of the steepnessof the curves representing differentcompositions indeed parallels their TMPC concentration. This agrees with previous results on pure polymersgJ6and blends4 and is consistent with the prediction of eq 6 that more intermolecularly coupled TMPC segmental relaxations will exhibit more marked temperature dependencies. Omitted from Figure 1 is the data for the blend with 20% TMPC. The maximum loss tangent of this blend is only about 60% larger than the maximum loss tangent of pure PS. This indicates that it is no longer a good approximation to associate the dielectric loss only with TMPC segments; contributions from PS segments have to be included. It is expected that relaxation of PS

Macromolecules, Vol. 25, No. 15, 1992 segmentsin this composition will have enhanced coupling parameters from that of pure PS and a concomitantsteeper temperature variation with (T-Tg)/Tg.This expectation is in fact consistent with experiment when comparing the 20% TMPC blend with pure PS. Nevertheless, in order to avoid any confusion, data for the 20 % TMPC blend has not been included in Figure 1.

Discussions and Summary In miscible blends of TMPC and PS segmental relaxation of TMPC exhibits properties similar to those of segmental relaxations of PVE in PVE/PIP blends and PS in PS/PVME blends. These common features include (1) the decrease of the average coupling parameter (which may reflect the peak local environment) with decrease of TMPC content and (2) a concomitant decrease in the steepness of the shift factor with normalized temperature as illustrated for TMPC/ difference variable (T-Tg)/Tg, PS blends in Figure 1. The dielectric studies of PVME/ PS and TMPC/PS blends have in common the fact that segmentalrelaxations of PS are suppressedin the dielectric response of the blend; only segmental relaxation of the other component is monitored. However, the influence of blending on the spectral response is diametrically different for these two mixtures. For blends of PVME the lower frequency dielectric response is dominated by local environmentsricher in the other component (PS),whereas for TMPC this region of the spectrum reflects environmenta richer in the TMPC itself. The couplingparameter for PVME segmental relaxation in any local environment of the PVME/PS blend is always larger than that of pure PVME. Contrarily, the coupling of TMPC segmental relaxation in any lcoal environment of the TMPC/PS blend is always weaker than that for pure TMPC. These differencesbetween the two blends are brought out in the context of the coupling model, and the former are consistent with the latter. The common characteristics of the segmentaldynamics of the two blends are (1) the large increase in the breadth of the dielectric loss curves compared with those of the pure polymers, (2) an extraordinary low-frequencytail to the dispersion, particularly at lower temperatures, and (3) an expectation (not yet verified for TMPC/PS mixtures) of failure of timetemperature superpositioning. These properties, all consistent with predictions of the coupling model, result primarily from the large difference in the Tis of the pure components (- 120deg for PVME/ PS and -93 deg for TMPC/PS). For TMPC/PS, the larger intermolecular coupling intrinsic to TMPC molecules (dielectrically n = 0.64 for pure TMPC) compared with PS molecules (dielectrically n = 0.46 for pure PS) may also be a factor.

Segmental Relaxation in TMPC/PS Blends 3909

It is anticipated that a very different dielectric response would be measured from a miscible blend whose components have similar 5”;s and coupling parameters in the pure state. Miscibleblends of polystrene/poly-2-chlorostyrene (PS/PoCS) apparently are an example of this situation. The difference in 5”;s is less than 30 deg, and dielectrically, the two pure polymers evidently have about the same coupling parameters (as suggested by the fact that their dielectric loss curves have a similar shape and breadth). Indeed, dielectric data on blends of PS/PoCS reveal a different behavior.16 In miscible PS/PoCS blends only a slight increase in the width of the dielectric loss curves was observed compared to the neat polymers. Although the data are limited, the reported temperature dependencies of the shift factors for the blend and the neat polymers suggestthat they are nearly equivalent when or Tg/T. This is in contrast plotted against (7’- Tg)/Tg to the large variation of the temperature dependency of the shift factor with blend compositionobserved in PVME/ PS4J0and TMPC/PS blends (Figure 1). It is tempting to call blends such as PS/PoCS “dynamically compatible”, in the sense that intermolecular coupling of segmental relaxations of the pure polymers are relatively unaltered upon mixing. Acknowledgment. The support of the Office of Naval Research (K.L.N. under Contract No. N0001491WX24087) is gratefully acknowledged. References and Notes Roland, C. M.; Ngai, K. L. Macromolecules 1991,24,2261. Traak, C. A.; Roland, C. M. Macromolecules 1989,22,256. Miller, J. B.;McGrath, K. J.; Roland, C. M.; Traak, C. A.; Garroway, A. N. Macromolecules 1990,23,4543. Roland, C. M.; Ngai, K. L. Macromolecules 1992,2,5,363. Colby, R. H.Polymer 1989,30, 1275. Ngai, K. L.;Plazek, D. J. Macromolecules 1990,23,4282. Zemel, I. S.;Roland, C. M. Polymer, in press. Ngai, K. L.; Rendell, R. W.; Rajagopal, A. K.; Teitler, S. Ann. N.Y. Acad. Sci. 1986,484,150. Roland, C. M.; Ngai, K. L. Macromolecules 1991,24,5315. Zetsche, A.; Kremer, F.; Jung, W.; Schulze, H. Polymer 1990, 31, 1883. O’Reilly, J. M.; Sedita, J. S.Mater Res. SOC.Symp. Proc. 1990, 171,225. O’Reilly, J. M.; Sedita, J. S. In press. Ngai, K. L.; Rendell, R. W. J. Non-Cryst. Solids 1991,131-133, 942 and references therein. See also ref 4. Yang, H.; O’Reilly, J. M. Mater. Res. SOC.Symp. Proc. 1987. 79, 129. Plazek, D.J.; Ngai, K. L. Macromolecules 1991,24, 1222. Alexandrovich, P.S.;Karasz, F. E.; MacKnight, W. J. J. Macromol. Sci.,Phys. 1980,B17,501.‘Alexandrovich,P. S.;Doctoral Thesis, University of Massachusetts, Amherst, MA, 1978. Registry No. PS, 9003-53-6; TMPC (copolymer), 52684-169;TMPC (SRU), 38797-88-5.